Réponses B thymodépendantes et thymoindépendantes PLAN B cell development and classification B cell activation Thymodependent B(2) cell response BMC 423 (IF) - 2007 Antonino Nicoletti Thymo-independent B cell response [Antibody effector mechanisms] www.u681.jussieu.fr -> Didactic Material -> M1 BMC 423 antonino.nicoletti@upmc.fr TD vs TI humoral immune responses Most antibody (B cell) responses need help = Thymus-Dependent (TD) responses Help comes from T cells (signal 2) Most help comes from T H 2 but T H 1 can also provide help T help controls or partly controls B cell proliferation, class switching, initiation of somatic mutations and memory Antigens that activate in this way are said to be thymus-dependent antigens There are also antibody responses that do not require T help = Thymus-independent (TI) antibody responses Antigens that activate in this way are said to be thymus-independent antigens B cell development and classification
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The BCR complex B cell activation The BCR complex The BCR complex
The BCR complex Thymodependent B(2) cell response Activation by antigen binding and helper T cell interactions T cells activate B cells that recognize the same Ag but not necessarily the same epitope Activation = proliferation and differentiation
=MHC class II B cell binds antigen in BCR, endocytoses the antigen, process it in to many different peptides and presents several of the peptides in association with MHC class II This is the epitope recognized by this B cell (peptide 68-74) Peptide 34-48 Peptide 80-93 Th cells can recognize any of these peptides and provide help Peptide 73-88 Peptide 12-25 (T cell activation up-regulates T cell expression of CD40L)
Signal 2 (CD40L) is required for class switching but T H cells make cytokines that influence isotype switching IL-4 is secreted in the direction of the B cell so there is little bystander effect on neighboring B cells IFN-g is a hallmark of cell-mediated immune responses so IgG3 and IgG2a are also associated with T H 1 responses (Mouse data) Topology of the thymodependent B cell response Topology of the thymodependent B cell response Those B cells and T cells that bind antigen are trapped in the T cell zone of the peripheral lymphoid organ where they can both get activated and interact Some B cells in the primary focus differentiate into plasmablasts and plasma cells, leave the area and make antibody. Others go to the B cell zone
Topology of the thymodependent B cell response Topology of the thymodependent B cell response Activated B cells eventually differentiate into plasma cells for the secretion of antibody and memory B cells. Most plasma cells survive for a few day to a few week. Some are longlived (account for much of the circulating antibodies). Memory B cell live a long time (years). Memory B cells keep the changes that they acquired in the germinal centers (e.g., class switched, somatic mutations). Although 50-100 different antigen-specific B cells originally comprise a GC, by the end of the response all the B cells are from 1 or a few clones Germinal centers (GC) contain antigen-specific B cells, follicular dendritic cells (FDC) and antigen-specific T cells Germinal centers are mostly proliferating B cells but also contain many (10%) T cells In the germinal centers, B cells undergo: 1.somatic hypermutations 2.affinity maturation 3.isotype switching Germinal centers (GC) contain antigen-specific B cells, follicular dendritic cells (FDC) and antigen-specific T cells FDC present native antigen: 1. bound by antibody and FcR 2. bound by complement and complement receptors Modification of the amount (proliferation), of the function (switch) and of the efficiency (affinity) of the antibodies Centrocyte = B cell; Centroblast = dividing B cell B cells competing to bind the antigens presented by FDCs= competition that drive affinity maturation
If T cells recognize only peptides, how do you make antibodies to polysaccharides or other non-protein macromolecules? Thymo-independent B cell response Some B cell responses require T help whereas other do not Thymo-independent Type 1 Thymo-independent Type 2 IgM LPS Sugars IgM T-independent antibody response generally have 1. no memory 2. no isotype switching 3. no somatic mutations B B Switch? T IgG B cells that respond to these Ags are mostly B1a cells
Properties of thymus-dependent and thymus-independent antigens B cell response to TI-1 antigens BCR signaling Cytokines Classic Required (from Th) Use the BCR as a focusing component that concentrates the polyclonal activator Required (from nonlymphoid cells) Target B cells Mature only Mature and immature Vigorous and prolonged Required (not necessarily from Th cells) Mature only These are polyclonal B cell activators or B cell mitogens. These can be dangerous because they deregulate B cell responsiveness At low doses, the TI-1 antigens activate only the antigen-specific B cells but they do it without T cell help. This can be helpful in getting rid rapidly of bacteria (without the need to expand Th cells) Bacterial lipopolysaccharides (LPS) is the prototypical TI-1 antigen Properties of thymus-dependent and thymus-independent antigens B cell response to TI-2 antigens TI-2 antigens contain highly repetitive structures (epitopes) Highly repetitive epitopes cross-link the BCRs and activate the B cells Bacterial capsule polysaccharides are prototypic TI-2 antigens BCR signaling Classic Use the BCR as a focusing component that concentrates the polyclonal activator Vigorous and prolonged Too low a density of repeating epitopes and they do not activate Too high a density of repeating epitopes and they anergize. Cytokines Required (from Th) Required (from nonlymphoid cells) Target B cells Mature only Mature and immature Required (not necessarily from Th cells) Mature only
B cell response to TI-2 antigens and the role of T cells Summary of different classes of antigens TI-2 responses exist in athymic mice Elimination of all and T cells blocks TI-2 B cell responses May be or CD4-/CD8- DN T cells with an extrathymic development which may interact with non classical MHC molecules (such as CD1) How can we help the immune system to make Abs to TI Ags such as polysaccharides (PS) and other non-protein macromolecules? Haemophilus influenzae type b vaccine How can we help the immune system to make Abs to TI Ags such as polysaccharides (PS) and other non-protein macromolecules? Haemophilus influenzae type b vaccine Prior to the introduction of effective Hib vaccines 20 years ago, Hib = the most common etiologic agent of serious bacterial infections in young children (<5 years) Though neonates <3months are rarely affected Hib PS = TI-2 Ag. Anti-Hib PS Abs=IgM (also IgG in humans) First generation vaccine: purified Hib PS: poor efficacy in children <2 years Second generation vaccines: Hib PS conjugated with one protein carrier - Diphteria toxoid (PRP-D): poor efficacy - Non-toxic diphteroid toxin (HbOC or HibTiter): OK with 3 inj - Meningococcal outer membrane (PRP-OMPC): OK with 1 inj <2 mo of age but not efficient >6 mo - Purified tetanus toxoid (PRP-T) : has the advantage of HbOC+PRP-OMPC = protein = polysaccharide
Some of the way that antibodies function to protect against infections [Antibody effector mechanisms] (how antibodies help get rid of antigens) Neutralization and inhibition of adherence Opsonization Complement activation Immune complex clearance by RBC ADCC Mast cell degranulation Eosinophil degranulation Neutralization of microbial agents Neutralization of microbial agents Most bacteria need to attach to a surface to initiate an infection Antibodies can prevent attachment of bacteria to cell surfaces Prevention of adhesion on mucus membranes is particularly important; this is a major role for secretory IgA
Complement activation Free Ig does not bind efficiently to FcR whereas antigen-antibody IC do bind efficiently (IgE-FcR is an exception) => free Igs and IC (Ig+Ag) do not compete with each other for FcR. This allows innate immunity to focus on targets already recognized by antibody IgM is highly efficient at fixing (activating) complement (A single molecule of IgM bound to a surface can initiate a complement cascade IgGs can fix complement but are less efficient (2 IgG can initiate a complement cascade but getting 2 bound molecules of IgG close together can take lots of IgG) IgM does not have free Fc regions and there are few Fc receptors for IgM. But IgM is efficient at complement activation and uses C3b for an opsonin (IgM is not an opsonin but it is very efficient at inducing production of C3b, a good opsonin). Fc receptors and complement receptors synergize to make phagocytosis of bacteria and other organisms very efficient Red blood cells (RBC) help clear immune complexes (antigen-antibody complexes) from the blood via complement receptors on the RBCs Immune complexes that are not removed from the blood in the liver or spleen tend to get deposited in the kidneys Antibodies can activate complement but complement can be activated without antibody This can cause glomerulonephritis (inflammation of the glomeruli) and kidney failure
Antibody dependent cell-mediated cytotoxicity (ADCC) IgE plus antigen causes degranulation of mast cells (granules contain histamine and other compounds that cause inflammation) Mast cells can bind antibodies with Fc R in the absence of antigen (unlike other FcRs) The binding affinity of Fc R for IgE is 100 to 50,000 time greater than the affinity of most other FcRs for antibody NK has two ways to recognize targets: (1) lack of MHC class I on the target (innate immunity) (2) antibody on the target (adaptive immunity)